DE2513183C3 - Heat engine system - Google Patents

Description

The invention relates to a heat engine system according to the preamble of claim 1.

Such a system is known from CH-PS 2 70 344. In this known system, in the case of the Heat exchanger, the air acting as a working medium is heated, the heater is structurally with the Combined heat exchanger, however, the heat exchanger operates in a conventional manner by having a Heat transfer from one gas stream heated by the heater to a second, the working medium forming gas flow (air) transfers by the regenerator first through the heated gas flow is heated and the heated channels are then flowed through by the working medium to be heated.

To use the work equipment for certain purposes, e.g. B. for starting or for a short time a higher one To achieve performance, to heat even further, is provided here in the working medium (air) before the Turbine still perform a combustion by injecting liquid fuel and burning it. As a result, the working medium, which is kept clean via the heat exchange of foreign substances should be contaminated again.

Another heat engine system of the type according to the preamble of claim 1 is known from US Pat. No. 9S,625. Here, too, a gaseous medium heated by the heater is brought into heat exchange with the working medium, specifically via the walls separating the two gas flows of a heat exchanger working as a hot air generator.
In both cases it can be achieved that in normal operation, ie without an upstream combustion system, the turbine is acted upon by clean gases, so that corrosion and erosion are reduced, but the efficiency of such systems is lower

ίο bad because the temperature difference between primary and secondary circuit of the heat exchanger is relatively small and with the usually available standing combustion chambers the primary temperature cannot be increased significantly because the for the Combustion chambers used materials cannot withstand a higher temperature.

The invention is therefore based on the object to provide a thermal power plant with a heater that with a very high temperature working medium works with the working medium separated from the combustion circuit is kept free from contamination.

This object is achieved according to the invention by the features set out in the characterizing part of claim 1 specified features.

Through this surface combustion it is achieved that the temperature of the working medium to a value which is higher than the temperature of the exhaust gases, because the walls of the Heat exchanger through the surface combustion to a temperature that of the flame temperature corresponds to, and this flame temperature is significantly higher than the exhaust gas temperature.

Although it is already known from DT-PS 10 77 821 a power plant that uses surface combustion, in this case with catalytic combustion, works; however, this is not a The gas flow separated from the flow of fuel gases is heated, but the flow from the compressor Air is heated in the primary circuit of the heat exchanger with surface combustion and the exhaust gases from the Primary circuit flow through the secondary circuit of the heat exchanger to further heat up the Primary circuit and thus to ensure an improvement in the combustion in the primary circuit. Around To be able to perform this function, the heated gas flow leaving the primary circuit must be at Flowing through the secondary circuit gives off heat so that the combustion in the primary circuit is catalytic Ways can be done.

Such a designed according to the invention heat engine system can be designed according to one embodiment of the invention as a gas turbine system be. The arrangement is expediently made such that the heat engine is a Gas turbine engine is. The combustion device is expediently connected downstream of the turbine and the turbine exhaust is used as an oxidant for the surface combustion. Through this this results in a favorable utilization of the waste heat.

According to a further embodiment of the invention it is provided that the system as a after Stirling principle working hot gas engine is formed.

For all purposes of use, the heat exchanger itself can be designed in a manner known per se either as a storage heat exchanger or as a recuperator. In the latter case, the storage heat exchanger is provided with liui Käiiäicü, ifi ucäScil wucrnäCiicFi uic

Combustion takes place. This second heat exchanger can also be used in a manner known per se have a rotatable matrix.

Exemplary embodiments of the invention are described below with reference to the drawing. In the Drawing shows

F i g. 1 is a schematic representation of a gas turbine engine enjoyed with a heating device of the invention,

F i g. FIG. 2 shows a perspective illustration of a heat exchanger for the engine according to FIG. 1.

F i g. 3 a schematic representation of a modified embodiment.

F i g. 1 shows eir. Gas turbine engine, which has an axial compressor 10, which compresses its air via an air inlet 11, and delivers the compressed air to a combustion device 12. The combustion device 12 has a heat exchanger channel 13 through which the compressed air passes, and in the channel 13 the air is in thermal contact with a surface combustion device 14, which is described further below. The air is thus heated in the duct 13 and flows off to an axial turbine 15, in which it expands and drives the turbine in the usual way. A shaft 16 connects the turbine to the compressor in a driving manner.

The air v, exiting from the turbine 15. d via a line 17 to a fuel injector 18 a Surface combustion device 14 out. The fuel injector 18 causes fuel, e.g. B. Kerosene or gaseous hydrocarbon fuel is intimately mixed with air, so that a combustible Mixture is formed once the surface incinerator 14 is reached. This facility can in detail be of different training. The main criterion is that the surface, which carries the surface burn phenomenon, has a sufficient areal extent. Preferably a bundle of fine silicon or aluminum tubes is used, so that the fuel-air mixture can flow out inside the tubes and the channel 13, which is arranged outside the tubes or vice versa. Instead, the tube bundle or a typical matrix could be part of a rotating heat exchanger as described below, or it could be a similar rotating heat exchanger with conventional Matrix can be used, provided that it has a sufficiently large surface area Is provided.

The fuel-air mixture preferably burns in the tubes and because of the relatively large surface area the combustion takes place as surface combustion. In the case of surface combustion, the Surface temperature raised to a temperature which is considerably higher than the temperature im Normal combustion would occur even though the fuel-air mixture is not stoichiometric needs to be.

Surface combustion devices are known and implemented in a wide variety of ways been. They have found industrial application at least since 1900.

The advantage of surface combustion is that the chemical reaction takes place on the surface and the temperature of the wall adjacent to this reaction is considerably higher than the temperature of the outflowing gas according to the air-fuel ratio of the reaction, an experiment carried out in a laboratory showed that when a kerosene-air mixture was burned with a temperature rise of 400 ^° C. corresponding to the relevant air-fuel ratio e: an exhaust gas temperature of 700 ^° C. resulted. The temperature of the wall of the surface incinerator was about 1600 ° C.

When using a heat transfer device to take the heat from the combustion air

ίο to transfer the working medium, then with normal arrangements the temperature difference available for transferring the heat would be based on a gas temperature of 700 ° C. The wall that separates the hot gas from the colder working fluid would stand at a temperature of less than 700 ⁰ C. By using a surface combustion device, the temperature of the wall is remarkably increased, and would in accordance with the embodiment, an increase occurring to a maximum possible value of 1600 ⁰ C. Accordingly, the temperature difference available for heat transfer is very large

The pipes therefore become very hot and the heat is transferred to the air within the duct 13.

The exhaust gases from the device 14 flow over a Channel 19 after another turbine, an exhaust nozzle or another place where another Use are supplied.

Fig. 2 shows the use of a rotating heat exchanger which forms both a surface combustion device and a heat exchanger with the compressor compressed air. In this case there is; a rotating heat exchanger made from a cylindrical bundle of fine silicon tubes 20 or from a typical matrix of ceramic or metal, the tubes being coaxial with the cylinder. The cylinder is rotatable about its axis on a shaft 21 and sealed inlet and outlet passages allow fuel-air flow over the tubes in sector 22, while the compressor air flows in the opposite direction over the remaining tubes or through some of them. The cylinder is rotated slowly by means not shown and surface combustion takes place within the tubes in the sector 22. These tubes are heated accordingly and when they leave sector 22 as a result of the rotation of the cylinder, they transfer their heat to the compressor air flow. The cylinder accordingly represents a surface combustion arrangement and a heat exchanger in one structural unit.

It is clear that conventional metal or ceramic dies for the rotary heat exchanger can be used can use. These can consist of windings of corrugated or flat metal or of ceramics, which contain strips that create a matrix having a plurality of axially extending channels. The size of the channels can be dimensioned differently from conventional heat exchangers to get the best surface burn results.

3 shows a modified embodiment. This corresponds essentially to the embodiment nacl. 1, however, it can be seen that a further heat exchanger 30 is provided in which the exhaust gases from the surface combustion device and the compressor compressed air are brought into heat exchange before entering the channel 13. In this way, the air contained in the Abeases is within the *

Engine used. The heat exchanger 30 can be a rotating heat exchanger as shown in FIG. 2 shown, his or her may have some other simple education.

It will be seen that the engine arrangement described is relatively simple, and it is clear that that too more complex arrangements, e.g. B. multi-shaft engines, can be modified in the way. So far has it has proven difficult to initiate a surface combustion in kerosene-air mixtures without only a light gas, such as. B. acetylene to preheat the surface combustion device to use. It may be necessary to use a different fuel to start the engine use and / or additional preheating means for the surface combustion device may prove necessary to be provided.

A tube bundle as described above proves to be particularly useful, but other arrangements can also be used, be For example, a quantity of particles or plates with textured surfaces made of different! Materials.

1 sheet of drawings

Claims (7)

Patent claims: 1. Consisting of a compressor, a heater and an expansion machine An engine system in which the heating device consists of a combustion device and there is a heat exchanger that transfers the heat generated in the latter to the working fluid, characterized in that in the combustion device (14) a surface combustion takes place and that the combustion surface through a heat transfer wall of the Heat exchanger is formed 2. Engine system according to claim 1, characterized in that it is a gas turbine system lit. 3. Engine system according to claim 2, characterized in that the secondary part (13) of the Heat exchanger of the heating device in the air flow between the compressor (10) and the turbine (15) is arranged 4. Engine system according to claim 3, characterized in that the combustion device (14) the turbine (15) is connected downstream and that the turbine exhaust air as an oxidizing agent for the surface combustion serves. 5. engine system according to claim 1, characterized in that it is one according to the The Stirling principle is working hot gas machine 6. Engine system according to one of claims I ₁ 2 or 5, characterized in that the heat exchanger is a storage heat exchanger, in the channels (20) of which the surface combustion takes place 7. Kraftmaschienenanlage according to claim 6, characterized in that the storage heat exchanger has a rotatable matrix.